Power amplifier and electronic device

ABSTRACT

The present disclosure provides a power amplifier and an electrical device. The two-stage power amplifier architecture is tuned staggered before power combining. A previous stage matching network and its input matching are split into a cascaded staggered tuning, such that the center frequency is at frequency point 1 less than the design frequency point and frequency point 2 greater than design frequency point, and then the power combining stage is tuned at the design frequency point. At advanced process nodes (such as 65 nm or below), compared with the known architecture, in-band signal quality and out-of-band filtering effect of the power amplifier chip integrating this architecture will be better when using the same number of transformers (same area), the reliability will be better. Due to its good flatness within the band, this architecture is especially suitable for carrier aggregation communication occasions.

TECHNICAL FIELD

The present disclosure relates to the technical field of integrated circuits and electronic devices, and in particular, to a power amplifier chip and an electronic device.

BACKGROUND

In the related arts, with the shrinking of process nodes of the Radio Frequency (RF) chip, the design of the power amplifier integrated with the RF chip will become difficult. Especially, designing high-power power amplifiers on the advanced process nodes (such as 65 nm or below) will face challenges because of the poor tolerance of voltage swing and current swing.

Referring to FIG. 1 (D. Chowdhury, C. D. Hull, O. B. Degani, Y Wang, and A. M. Niknej ad, “A fully integrated dual-mode highly linear 2.4 Ghz CMOS power amplifier”, IEEE J. Solid-State Circuits, vol. 43, no. 3, pp. 600-609, March 2009) and FIG. 2 (Y. Tan, H, Xu. (2016) CMOS power amplifier design for wireless connectivity applications: a highly linear WLAN power amplifier in advanced SoC CMOS, In RF and mm-wave Power Generation in Silicon (pp. 61-pp. 87). Elsevier Inc. DOI:10.1016/B978-0-12-408052-2.00008-6), FIG. 1 and FIG. 2 show two architectures of amplifiers commonly used in the related arts. As shown in FIG. 1, 1 represents an input transformer, 2 represents an inter-stage power splitter, 3 represents an output stage 2 (identical to stage 1), and 4 represents a power combiner. As shown in FIG. 2, 5 represents an input matching power splitter, 6 represents an inter-stage matching, and 7 represents an output matching power combiner. As can be seen from FIG. 1 and FIG. 2, there are many inductors in the existing architecture, the usable area is large, thus the cost is high, and the tuning bandwidth is relatively small.

In advanced CMOS process nodes (such as: 65 nm or below), the staggered tuning RF technology is combined with the power combining technology to enable power amplifiers to achieve better performance and lower area cost.

In theory, if n single-tuned amplifiers with the same bandwidth are tuned at the same frequency point, then:

$\begin{matrix} {r = {\frac{\Delta \; f_{system}}{\Delta \; f_{single}} = \sqrt{2^{\frac{1}{n}} - 1}}} & (1) \end{matrix}$

r represents the bandwidth reduction rate, which is defined as the ratio of the bandwidth (HZ) of a cascaded circuit (Δf_(system)) to the bandwidth (HZ) of a single-stage circuit (Δf_(single)).

When the gain of each stage is equal, the system gain and system bandwidth satisfy the following formula:

$\begin{matrix} {{\Delta \; f_{system}} = \frac{f_{t}\sqrt{2^{\frac{1}{n}} - 1}}{A_{system}^{\frac{1}{n}}}} & (2) \end{matrix}$

A_(system) is the system gain of a cascaded circuit; f_(t) is the transition frequency, which is related to the bias conditions and system properties,

$f_{t} = {\frac{gm}{2\pi \; C_{p}}.}$

When the transformer resonates, as shown in FIG. 1 and FIG. 2, the 2-stage power amplifier, input matching, inter-stage matching, and output matching are all tuned at the same frequency point, the gain, band selectivity, in-band group delay, gain flatness, and system efficiency are highly coupled. Depending on different process and bias conditions, the transition frequency is different and the design space will become narrower, requiring complex compromises. The gain allocation and bias conditions will be optimized for efficiency, which will be severely limited in bandwidth.

SUMMARY

The main objective of the present disclosure is to provide a power amplifier, which aims to ensure the gain of the signal within the bandwidth, achieve flat group delay, improve the signal quality, reduce the usable area, increase reliability and efficiency.

In order to achieve the above objective, the present disclosure provides a power amplifier, including a staggered tuning circuit and a power combining circuit including two pseudo differential pair amplifiers. An output end of the staggered tuning circuit is connected to an input end of the power combining circuit.

The staggered tuning circuit is configured to: split a stage matching network and its input matching into a cascaded tuning circuit, and set center frequencies of parallel resonance networks of different stages to be different values through a setting relationship, and drive the power combining circuit of a subsequent stage.

The power combining circuit is configured to combine output powers of the two pseudo differential pair amplifiers to obtain a combined power amplification signal.

Optionally, the staggered tuning circuit includes an input matching network, a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the input matching network is connected to an input end of the first amplifier; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.

Optionally, the staggered tuning circuit includes a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.

Optionally, the setting relationship is to multiply or divide a preset frequency value and a coordination coefficient to obtain center frequencies of parallel resonance networks of different stages; the preset frequency value is a center frequency of the power amplifier; and the coordination coefficient is obtained according to a required system bandwidth and its in-band flatness.

Optionally, the power combining circuit includes a third amplifier, a fourth amplifier, and a power combining resonance network; the third amplifier is in parallel with the fourth amplifier; and an output end of the third amplifier and an output end of the fourth amplifier are both connected to an input end of the power combining resonance network.

Optionally, the third amplifier and the fourth amplifier are both a cascaded three-stage pseudo differential pair; the third amplifier and the fourth amplifier have a same internal structure, and each includes a first deep N-well N-MOS tube, a second deep N-well N-MOS tube, a third deep N-well N-MOS tube, a fourth deep N-well N-MOS tube, a first N-MOS tube, a second N-MOS tube, a first resistor, a second resistor, a third resistor, a fourth resistor, a fifth resistor, a sixth resistor, a seventh resistor, and an eighth resistor; a deep N-well of the first deep N-well N-MOS tube is connected to a first end of the first resistor, a second end of the first resistor is connected to a first end of the second resistor and connected to a power supply voltage, and a second end of the second resistor is connected to a deep N-well of the second deep N-well N-MOS tube; a body end of the first deep N-well N-MOS tube is connected to a first end of the third resistor, a second end of the third resistor is connected to a source of the first deep N-well N-MOS tube and connected to a drain of the third deep N-well N-MOS tube; a body end of the second deep N-well N-MOS tube is connected to a first of the fourth resistor, a second end of the fourth resistor is connected to a source of the second deep N-well N-MOS tube and connected to a drain of the fourth deep N-well N-MOS tube; a deep N-well of the third deep N-well N-MOS tube is connected to a first end of the fifth resistor, a second end of the fifth resistor is connected to a first end of the sixth resistor and connected to the power supply voltage, a second end of the sixth resistor is connected to a deep N-well of the fourth deep N-well N-MOS tube; a body end of the third deep N-well N-MOS tube is connected to a first end of the seventh resistor, a second end of the seventh resistor is connected to a source of the third deep N-well N-MOS tube and connected to a drain of the first N-MOS tube; a body end of the fourth deep N-well N-MOS tube is connected to a first end of the eighth resistor, a second end of the eighth resistor is connected to a source of the fourth deep N-well N-MOS tube and connected to a drain of the second N-MOS tube; and a source of the first N-MOS tube is connected to a source of the second N-MOS tube and grounded.

Optionally, the first deep N-well N-MOS tube and the second deep N-well N-MOS tube are both a deep N-well normal voltage threshold thick gate oxide N-MOS tube.

Optionally, the third deep N-well N-MOS tube and the fourth deep N-well N-MOS tube are both a deep N-well low voltage threshold thin gate oxide N-MOS tube.

Optionally, the first N-MOS tube and the second N-MOS tube are both a low voltage threshold thin gate oxide N-MOS tube.

The present disclosure further provides an electronic device, including a power amplifier. The power amplifier includes a staggered tuning circuit and a power combining circuit including two pseudo differential pair amplifiers. An output end of the staggered tuning circuit is connected to an input end of the power combining circuit.

The staggered tuning circuit is configured to: split a previous stage matching network and its input matching into a cascaded tuning circuit, and set center frequencies of parallel resonance networks of different stages to be different values through a setting relationship, and drive the power combining circuit of a subsequent stage.

The power combining circuit is configured to combine output powers of the two pseudo differential pair amplifiers to obtain a combined power amplification signal.

Optionally, the staggered tuning circuit includes an input matching network, a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the input matching network is connected to an input end of the first amplifier; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.

Optionally, the staggered tuning circuit includes a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.

Optionally, the setting relationship is to multiply or divide a preset frequency value and a coordination coefficient to obtain center frequencies of parallel resonance networks of different stages; the preset frequency value is a center frequency of the power amplifier; and the coordination coefficient is obtained according to a required system bandwidth and its in-band flatness.

Optionally, the power combining circuit includes a third amplifier, a fourth amplifier, and a power combining resonance network; the third amplifier is in parallel with the fourth amplifier; and an output end of the third amplifier and an output end of the fourth amplifier are both connected to an input end of the power combining resonance network.

Optionally, the third amplifier and the fourth amplifier are both a cascaded three-stage pseudo differential pair; the third amplifier and the fourth amplifier have a same internal structure, and each includes a first deep N-well N-MOS tube, a second deep N-well N-MOS tube, a third deep N-well N-MOS tube, a fourth deep N-well N-MOS tube, a first N-MOS tube, a second N-MOS tube, a first resistor, a second resistor, a third resistor, a fourth resistor, a fifth resistor, a sixth resistor, a seventh resistor, and an eighth resistor; a deep N-well of the first deep N-well N-MOS tube is connected to a first end of the first resistor, a second end of the first resistor is connected to a first end of the second resistor and connected to a power supply voltage, and a second end of the second resistor is connected to a deep N-well of the second deep N-well N-MOS tube; a body end of the first deep N-well N-MOS tube is connected to a first end of the third resistor, a second end of the third resistor is connected to a source of the first deep N-well N-MOS tube and connected to a drain of the third deep N-well N-MOS tube; a body end of the second deep N-well N-MOS tube is connected to a first of the fourth resistor, a second end of the fourth resistor is connected to a source of the second deep N-well N-MOS tube and connected to a drain of the fourth deep N-well N-MOS tube; a deep N-well of the third deep N-well N-MOS tube is connected to a first end of the fifth resistor, a second end of the fifth resistor is connected to a first end of the sixth resistor and connected to the power supply voltage, a second end of the sixth resistor is connected to a deep N-well of the fourth deep N-well N-MOS tube; a body end of the third deep N-well N-MOS tube is connected to a first end of the seventh resistor, a second end of the seventh resistor is connected to a source of the third deep N-well N-MOS tube and connected to a drain of the first N-MOS tube; a body end of the fourth deep N-well N-MOS tube is connected to a first end of the eighth resistor, a second end of the eighth resistor is connected to a source of the fourth deep N-well N-MOS tube and connected to a drain of the second N-MOS tube; and a source of the first N-MOS tube is connected to a source of the second N-MOS tube and grounded.

Optionally, the first deep N-well N-MOS tube and the second deep N-well N-MOS tube are both a deep N-well normal voltage threshold thick gate oxide N-MOS tube.

Optionally, the third deep N-well N-MOS tube and the fourth deep N-well N-MOS tube are both a deep N-well low voltage threshold thin gate oxide N-MOS tube.

Optionally, the first N-MOS tube and the second N-MOS tube are both a low voltage threshold thin gate oxide N-MOS tube.

In the technical solutions of the present disclosure, the two-stage power amplifier architecture is tuned staggered before power combining. Besides, in the present disclosure, a previous stage matching network and its input matching are split into a cascaded staggered tuning, such that its center frequency is at frequency 1 and frequency 2, and the last stage is tuned at frequency 3. Since the staggered tuning split in the previous stage widens the bandwidth, so even if the tuning network in the last stage reduces the bandwidth, it will not weaken too much. At advanced process nodes (such as 65 nm or below), compared with the known architecture, in-band signal quality and band filtering of the power amplifier chip integrating this architecture will be better when using the same number of transformers (same area). Due to its good flatness within the band, this architecture is especially suitable for carrier aggregation communication occasions.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the embodiments of the present disclosure or the technical solutions in the related art, the drawings used in the embodiments or the related art will be briefly described below. Obviously, the drawings in the following description are only some embodiments of the present disclosure. It will be apparent to those skilled in the art that other figures can be obtained from the structures illustrated in the drawings without the inventive effort.

FIG. 1 is a schematic structural diagram of a first known amplifier structure;

FIG. 2 is a schematic structural diagram of a second known amplifier structure;

FIG. 3 is a schematic diagram of functional modules of a power amplifier according to the present disclosure;

FIG. 4 is a schematic structural diagram of the power amplifier with an input stage matching staggered tuning circuit according to a first embodiment of the present disclosure;

FIG. 5 is a schematic structural diagram of the power amplifier without the input stage matching staggered tuning circuit according to a second embodiment of the present disclosure;

FIG. 6 is a schematic diagram of a power combining circuit of the power amplifier according to a third embodiment of the present disclosure;

FIG. 7 is a schematic diagram of an internal amplifier circuit of the power combining circuit of the power amplifier according to a fourth embodiment of the present disclosure;

FIG. 8 is a schematic diagram of a power amplifier architecture when the power amplifier does not include an input stage matching according to a fifth embodiment of the present disclosure;

FIG. 9 is a schematic diagram of the power amplifier architecture when the power amplifier includes the input stage matching according to a sixth embodiment of the present disclosure;

FIG. 10 is a schematic diagram of a frequency response of the power amplifier without an input matching stagger tuning according to the present disclosure;

FIG. 11 is a schematic diagram of the frequency response of the power amplifier with the input matching stagger tuning according to the present disclosure; and

FIG. 12 is a schematic diagram of the frequency response during overlapping tuning.

The realization of the objective, functional characteristics, advantages of the present disclosure are further described with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The technical solutions of the embodiments of the present disclosure will be clearly and completely described in the following with reference to the accompanying drawings. It is obvious that the embodiments to be described are only a part rather than all of the embodiments of the present disclosure. All other embodiments obtained by persons skilled in the art based on the embodiments of the present disclosure without creative efforts shall fall within the protection scope of the present disclosure.

It is to be understood that, all of the directional instructions in the embodiments of the present disclosure (such as up, down, left, right, front, rear . . . ) can only be used for explaining relative position relations, moving condition of the elements under a special form (referring to figures), and so on, if the special form changes, the directional instructions changes accordingly.

In addition, the descriptions, such as the “first”, the “second” in the embodiment of present disclosure, can only be used for describing the aim of description, and cannot be understood as indicating or suggesting relative importance or impliedly indicating the number of the indicated technical feature. Therefore, the feature indicated by the “first”, the “second” can express or impliedly include at least one feature. Besides, the technical solution of each embodiment can be combined with each other, however the technical solution must base on that the ordinary skill in that art can realize the technical solution, when the combination of the technical solutions is contradictory or cannot be realized, it should consider that the combination of the technical solutions does not exist, and is beyond the protection scope of the present disclosure.

The present disclosure provides a power amplifier.

As shown in FIG. 3, the power amplifier of the present disclosure includes a staggered tuning circuit 100 and a power combining circuit 200 including two pseudo differential pair amplifiers. An output end of the staggered tuning circuit 100 is connected to an input end of the power combining circuit 200.

The staggered tuning circuit 100 is configured to split a previous stage matching network and its input matching into a cascaded tuning circuit, and set center frequencies of parallel resonance networks of different stages to be different values through a setting relationship, and drive the power combining circuit 200 of a subsequent stage.

The power combining circuit 200 is configured to combine output powers of the two pseudo differential pair amplifiers to obtain a combined power amplification signal.

In the present disclosure, the two-stage power amplifier architecture is tuned staggered before power combining, compared with the known architecture, in-band signal quality and band filtering will be better when using the same number of transformers (same area). Due to its good flatness within the band, this architecture is especially suitable for carrier aggregation communication occasions.

The staggered tuning circuit 100 of the present disclosure includes an input stage matching staggered tuning circuit and without the input stage matching staggered tuning circuit.

Referring to FIG. 4, in an embodiment of the present disclosure, the staggered tuning circuit 100 includes an input matching network M₁, a first amplifier A₁, a second amplifier A₂, a first inter-stage matching network M₂, and a second inter-stage matching network M₃. An output end of the input matching network M₁is connected to an input end of the first amplifier A₁. An output end of the first amplifier A₁ is connected to an input end of the first inter-stage matching network M₂. An output end of the first inter-stage matching network M₂ is connected to an input end of the second amplifier A₂. An output end of the second amplifier A₂ is connected to an input end of the second inter-stage matching network M₃.

Set the center frequencies of the first inter-stage matching network M₂ and the second inter-stage matching network M₃ at different values staggered by the setting relationship. Specially, the first inter-stage matching network M₂ is tuned at f₀/alpha, and the second inter-stage matching network M₃ is tuned at f₀×alpha. Generally f₀ is at the center frequency of the power amplifier. The parameter alpha is a dimensionless design parameter, which is selected according to the required system bandwidth and its in-band flatness. According to the present embodiment, a previous stage matching network and its input matching are split into a cascaded staggered tuning, such that its center frequency is at frequency 1 and frequency 2, and the last stage is tuned at frequency 3. Since the staggered tuning split in the previous stage widens the bandwidth, so even if the tuning network in the last stage reduces the bandwidth, it will not weaken too much.

Referring to FIG. 6, according to an embodiment of the present disclosure, the power combining circuit 200 includes a third amplifier A₃, a fourth amplifier A₄, and a power combining resonance network. The third amplifier A₃ is in parallel with the fourth amplifier A₄; and an output end of the third amplifier A₃ and an output end of the fourth amplifier A₄ are both connected to an input end of a power combining resonance network. In the present embodiment, two amplifiers are connected in parallel to a power combining resonance network, which saves the number of transformers used.

In the present disclosure, the third amplifier A₃ and the fourth amplifier A₄ are both a cascaded three-stage pseudo differential pair. Referring to FIG. 7, the third amplifier A₃ and the fourth amplifier A₄ have the same internal structure, and each includes a first deep N-well N-MOS tube M_(3m), a second deep N-well N-MOS tube M_(3p), a third deep N-well N-MOS tube M_(2m), a fourth deep N-well N-MOS tube M_(2p), a first N-MOS tube M_(1m), a second N-MOS tube M_(1p), a first resistor R_(3m2), a second resistor R_(3p2), a third resistor R_(3m1), a fourth resistor R_(3p2), a fifth resistor R_(2m2), a sixth resistor R_(2p2), a seventh resistor R_(2m1), and an eighth resistor R_(2p1).

In an optional embodiment, the first deep N-well N-MOS tube M_(3m) and the second deep N-well N-MOS tube M_(3p) are both a deep N-well normal voltage threshold thick gate oxide N-MOS tube, which are 6-port devices. Its deep N-well is biased at a higher supply voltage through a large resistor (R_(3m2), R_(3p2)); its body ends are connected to its own source through a large resistor (R_(3m1), R_(3p1), 10 Kohm). Its gate is biased at a higher voltage, so that the high-voltage swing on p_(m), p_(p) does not exceed its drain-gate tolerance limit. The third deep N-well N-MOS tube M_(2m) and the fourth deep N-well N-MOS tube M_(2p) are both a deep N-well low voltage threshold thin gate oxide N-MOS tube, which are 6-port devices. Its deep N-well is biased at a higher supply voltage through a large resistor (R_(2m2), R_(2p2)); its body ends are connected to its own source through a large resistor (R_(2m1), R_(2p1), 10 Kohm). The first N-MOS tube M_(1m) and the second N-MOS tube M_(1p) are both a low voltage threshold thin gate oxide N-MOS tube, which are 4-port devices.

The threshold voltage arrangements of the first N-MOS tube M_(1m), the second N-MOS tube M_(1p), the third deep N-well N-MOS tube M_(2m), and the fourth deep N-well N-MOS tube M_(2p) are to reduce the on-resistance R_(on), thereby reducing the knee voltage V_(knee); Because R_(on), V_(knee) and the maximum current I_(max) have the following formula:

V _(knee) =I×R _(on)  (3)

thereby improving the efficiency of the power amplifier. The uppermost first deep N-well N-MOS tube M_(3m) and the second deep N-well N-MOS tube M_(3p) exist for reliability design, to make the voltage drop swing of each port of the two thin gate oxide layers within the tolerance range.

The on-chip power combining method will also improve efficiency than the method that uses a larger conversion ratio matching network to transmit power without using a combining method; which is as shown in the following formula:

$\begin{matrix} {\eta_{tf} = \frac{Q_{ind}^{2} + 1}{Q_{ind}^{2} + \frac{r + \sqrt{r^{2} + {4{Q_{ind}\left( {r - 1} \right)}}}}{2}}} & (4) \end{matrix}$

η_(tf) is the power transmission efficiency of the transformer; Q² _(ind) is its quality factor; r represents the impedance conversion ratio.

Referring to FIG. 7, in an optional embodiment, a deep N-well of the first deep N-well N-MOS tube M_(3m) is connected to a first end of the first resistor R_(3m2), a second end of the first resistor R_(3m2) is connected to a first end of the second resistor R_(3p2) and connected to a power supply voltage V_(dd), a second end of the second resistor R_(3p2) is connected to a deep N-well of the second deep N-well N-MOS tube M_(3p). A body end of the first deep N-well N-MOS tube M_(3m) is connected to a first end of the third resistor R_(3m1), a second end of the third resistor R_(3m1) is connected to a source of the first deep N-well N-MOS tube M_(3m) and connected to a drain of the third deep N-well N-MOS tube M_(2m). A body end of the second deep N-well N-MOS tube M_(3p) is connected to a first of the fourth resistor R_(3p2), a second end of the fourth resistor R_(3p2) is connected to a source of the second deep N-well N-MOS tube M_(3p) and connected to a drain of the fourth deep N-well N-MOS tube M_(2p). A deep N-well of the third deep N-well N-MOS tube M_(2m) is connected to a first end of the fifth resistor R_(2m2), a second end of the fifth resistor R_(2m2) is connected to a first end of the sixth resistor R_(2p2) and connected to the power supply voltage V_(dd), a second end of the sixth resistor R_(2p2) is connected to a deep N-well of the fourth deep N-well N-MOS tube M_(2p). A body end of the third deep N-well N-MOS tube M_(2m) is connected to a first end of the seventh resistor R_(2m1), a second end of the seventh resistor R_(2m1) is connected to a source of the third deep N-well N-MOS tube M_(2m) and connected to a drain of the first N-MOS tube M_(1m). A body end of the fourth deep N-well N-MOS tube M_(2p) is connected to a first end of the eighth resistor R_(2p1), a second end of the eighth resistor R_(2p1) is connected to a source of the fourth deep N-well N-MOS tube M_(2p) and connected to a drain of the second N-MOS tube M_(1p). A source of the first N-MOS tube M_(2p) is connected to a source of the second N-MOS tube M_(1p) and connected to V_(SS).

In an optional embodiment, all amplifiers of the present disclosure are biased under deep AB, and the setting of the tube parameters and the bias voltage should enable deep AB operation. The design parameters of A1 and A2 are the same and the type is AX; the design parameters of A3 and A4 are the same and the type is AY. In AX, the widths of the three tubes from top to bottom are AX.W1, AX.W2, and AX.W3 respectively; then in AY, the widths of the three tubes are AY.W1, AY.W2, and AY.W3. AX.W1=a×AY.W1, AX.W2=a×AY.W2, AX.W3=a×AY.W3. And, a is a number between one thirty-two and one-half.

In an optional embodiment, the transformer of the present disclosure refers to the on-chip planar spiral transformer and stacked spiral transformer commonly used in CMOS radio frequency integrated circuits. The design should be based on the application and area constraints. The appropriate k (mutual inductance), L₁ (self-inductance of the primary coil), L₂ (self-inductance of the secondary coil), R, and C is selected to design enough gain and sufficient bandwidth. Besides, the resonant transformer network needs to be designed to meet the matching requirements. For the Txfmr3 and Txfmr4 resonant networks, they need to be designed to meet the optimal output power matching of the output saturation power Psat. For the resonant networks of Txfmr₁ and Txfmr₂, they need to be designed to meet the flatness requirements of the staggered tuning bandwidth and achieve a power ratio a.

The overall circuit architecture of the staggered tuning circuit 100 and the power combining circuit 200 connected in the present disclosure is as follows:

Referring to FIG. 8 and FIG. 9, V_(dd) is the supply voltage, Vcg1 is the bias voltage; A1, A2, A3, and A4 are amplifiers. As shown in FIG. 9, C₀ and C₂ are tuning capacitors. C₁ plays the role of suppressing even harmonics and common mode components. C₃, C₄, C₅, C₆, C₇, C₈ and C₉ are tuning capacitors. The tuning capacitor can be partially implemented by a programmable switched capacitor array and should be covered by this patent. As shown in FIG. 8, C₁₀ and C₁₁ are AC coupling capacitors. Txfmr₀, Txfmr₁, Txfmr₂ transformers have center taps on the primary and secondary coils, which are 6-port devices. A RC series array should be added to the center tap of the main coil to suppress self-excitation and stabilize the supply voltage. A capacitor can be optionally added to the center tap of the secondary coil to ground to suppress even-order harmonics and common-mode drift. Txfmr₃, Txfmr₄ transformers have no center tap in the secondary coil. R₃ and R₄ are the termination resistances of the secondary coil, which are selected according to the required system bandwidth and the flatness of the band. R₁ and R₂ are bias resistors, which generally have large resistances greater than 10 kOhm.

Referring to FIG. 8, when there is no input stage matching, the resonance network M₂ composed of Txfmr₁ and C₃, C₄, and R₃, and the resonance network M₃ composed of Txfmr₂ and C₅, C₆, and R₄ need to be designed in a form of staggered tuning that satisfies the flatness of the bandwidth and enables the power ratio a to be achieved.

Referring to FIG. 9, FIG. 9 is a schematic diagram of the power amplifier architecture when the power amplifier includes the input stage matching. The power combining resonant network composed of Txfmr₃, Txfmr₄ and C₇, C₈, and C₉ needs to be designed to meet the optimal output power matching of the output saturation power Psat. The input stage matching M1 composed of Txfmr₀, C₀, C₁, C₂ and R₁, the resonance network M₂ composed of Txfmr₁ and C₃, C₄, and R₃, and the resonance network M₃ composed of Txfmr₂ and C₅, C₆, and R₄ need to be designed in a form of staggered tuning that satisfies the flatness of the bandwidth and enables the power ratio a to be achieved.

In the present embodiment, at advanced process nodes, compared with the known architecture, in-band signal quality and band filtering of the power amplifier chip integrating this architecture will be better when using the same number of transformers (same area). Due to its good flatness within the band, this architecture is especially suitable for carrier aggregation communication occasions.

Referring to FIG. 10, FIG. 10 is a schematic diagram of a frequency response of the power amplifier without an input matching stagger tuning. Referring to FIG. 11, FIG. 11 is a schematic diagram of the frequency response of the power amplifier with the input matching stagger tuning. In the Figure, the horizontal axis is frequency (Hz), and the vertical axis is the frequency response mode (dB). Line 8 is the frequency response curve of the system input to output (FIG. 8 corresponds to FIG. 10, FIG. 9 corresponds to FIG. 11). Line 9 is the frequency response of A₁+M₁, and its tuning frequency is at f₀/alpha. Line 10 is the frequency response of A₂+M₂, its tuning frequency is at f₀×alpha. Line 11 is the frequency response diagram of M₁+A₀. It assumes that the input matching is driven by A₀. A₀ is a driver amplifier to be added as appropriate, and is not drawn in the circuit (FIG. 9 or FIG. 8).

Referring to FIG. 12, FIG. 12 is a schematic diagram of the frequency response during overlapping tuning. As shown in FIG. 12, Line 9 is the single frequency response of the amplifier tuned at the center frequency of 2.4G. When two amplifiers are cascaded, the frequency response of the system is shown by the green line. It can be seen that the bandwidth is reduced and the flatness of the in-band gain response is poor. Comparing FIG. 10 and FIG. 11 with FIG. 12, it can be seen that the in-bands in FIG. 10 and FIG. 11 are flattened and the bandwidth is increased, but the out-of-band suppression capability is not sacrificed.

The present disclosure further provides an electronic device. The electronic device includes a power amplifier as described above. The electronic device includes all the embodiments of the power amplifier described above, and therefore also has the same technical effects as the embodiments of the power amplifier, which will not be repeated here.

The above are only preferred embodiments of the present disclosure, and thus do not limit the scope of the present disclosure. Under the concept of the present disclosure, the equivalent structural transformations made by the present specification and the drawings are directly or indirectly applied to other related technical fields, and are included in the scope of the present disclosure. 

What is claimed is:
 1. A power amplifier, comprising a staggered tuning circuit and a power combining circuit comprising two pseudo differential pair amplifiers, wherein: an output end of the staggered tuning circuit is connected to an input end of the power combining circuit; the staggered tuning circuit is configured to: split a previous stage matching network and its input matching into a cascaded tuning circuit, and set center frequencies of parallel resonance networks of different stages to be different values through a setting relationship, and drive the power combining circuit of a subsequent stage; and the power combining circuit is configured to combine output powers of the two pseudo differential pair amplifiers to obtain a combined power amplification signal.
 2. The power amplifier of claim 1, wherein: the staggered tuning circuit comprises an input matching network, a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the input matching network is connected to an input end of the first amplifier; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.
 3. The power amplifier of claim 1, wherein: the staggered tuning circuit comprises a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.
 4. The power amplifier of claim 1, wherein: the setting relationship is to multiply or divide a preset frequency value and a coordination coefficient to obtain center frequencies of parallel resonance networks of different stages; the preset frequency value is a center frequency of a working passband of the power amplifier; and the coordination coefficient is obtained according to a required system bandwidth and its in-band flatness.
 5. The power amplifier of claim 1, wherein: the power combining circuit comprises a third amplifier, a fourth amplifier, and a power combining resonance network; the third amplifier is in parallel with the fourth amplifier; and an output end of the third amplifier and an output end of the fourth amplifier are both connected to an input end of the power combining resonance network.
 6. The power amplifier of claim 5, wherein: the third amplifier and the fourth amplifier are both a cascaded three-stage pseudo differential pair; the third amplifier and the fourth amplifier have a same internal structure, and each comprises a first deep N-well N-MOS tube, a second deep N-well N-MOS tube, a third deep N-well N-MOS tube, a fourth deep N-well N-MOS tube, a first N-MOS tube, a second N-MOS tube, a first resistor, a second resistor, a third resistor, a fourth resistor, a fifth resistor, a sixth resistor, a seventh resistor, and an eighth resistor; a deep N-well of the first deep N-well N-MOS tube is connected to a first end of the first resistor, a second end of the first resistor is connected to a first end of the second resistor and connected to a power supply voltage, and a second end of the second resistor is connected to a deep N-well of the second deep N-well N-MOS tube; a body end of the first deep N-well N-MOS tube is connected to a first end of the third resistor, a second end of the third resistor is connected to a source of the first deep N-well N-MOS tube and connected to a drain of the third deep N-well N-MOS tube; a body end of the second deep N-well N-MOS tube is connected to a first of the fourth resistor, a second end of the fourth resistor is connected to a source of the second deep N-well N-MOS tube and connected to a drain of the fourth deep N-well N-MOS tube; a deep N-well of the third deep N-well N-MOS tube is connected to a first end of the fifth resistor, a second end of the fifth resistor is connected to a first end of the sixth resistor and connected to the power supply voltage, a second end of the sixth resistor is connected to a deep N-well of the fourth deep N-well N-MOS tube; a body end of the third deep N-well N-MOS tube is connected to a first end of the seventh resistor, a second end of the seventh resistor is connected to a source of the third deep N-well N-MOS tube and connected to a drain of the first N-MOS tube; a body end of the fourth deep N-well N-MOS tube is connected to a first end of the eighth resistor, a second end of the eighth resistor is connected to a source of the fourth deep N-well N-MOS tube and connected to a drain of the second N-MOS tube; and a source of the first N-MOS tube is connected to a source of the second N-MOS tube and grounded.
 7. The power amplifier of claim 6, wherein: the first deep N-well N-MOS tube and the second deep N-well N-MOS tube are both a deep N-well normal voltage threshold thick gate oxide N-MOS tube.
 8. The power amplifier of claim 6, wherein: the third deep N-well N-MOS tube and the fourth deep N-well N-MOS tube are both a deep N-well low voltage threshold thin gate oxide N-MOS tube.
 9. The power amplifier of claim 6, wherein: the first N-MOS tube and the second N-MOS tube are both a low voltage threshold thin gate oxide N-MOS tube.
 10. An electronic device, comprising a power amplifier comprising a staggered tuning circuit and a power combining circuit comprising two pseudo differential pair amplifiers, wherein: an output end of the staggered tuning circuit is connected to an input end of the power combining circuit; the staggered tuning circuit is configured to: split a previous stage matching network and its input matching into a cascaded tuning circuit, and set center frequencies of parallel resonance networks of different stages to be different values defined through a setting relationship, and drive the power combining circuit of a subsequent stage; and the power combining circuit is configured to combine output powers of the two pseudo differential pair amplifiers to obtain a combined power amplification signal.
 11. The electronic device of claim 10, wherein: the staggered tuning circuit comprises an input matching network, a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the input matching network is connected to an input end of the first amplifier; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.
 12. The electronic device of claim 10, wherein: the staggered tuning circuit comprises a first amplifier, a second amplifier, a first inter-stage matching network, and a second inter-stage matching network; an output end of the first amplifier is connected to an input end of the first inter-stage matching network; an output end of the first inter-stage matching network is connected to an input end of the second amplifier; and an output end of the second amplifier is connected to an input end of the second inter-stage matching network.
 13. The electronic device of claim 10, wherein: the setting relationship is to multiply or divide a preset frequency value and a coordination coefficient to obtain center frequencies of parallel resonance networks of different stages; the preset frequency value is a center frequency of a working passband of the power amplifier; and the coordination coefficient is obtained according to a required system bandwidth and its in-band flatness.
 14. The electronic device of claim 10, wherein: the power combining circuit comprises a third amplifier, a fourth amplifier, and a power combining resonance network; the third amplifier is in parallel with the fourth amplifier; and an output end of the third amplifier and an output end of the fourth amplifier are both connected to an input end of the power combining resonance network.
 15. The electronic device of claim 14, wherein: the third amplifier and the fourth amplifier are both a cascaded three-stage pseudo differential pair; the third amplifier and the fourth amplifier have a same internal structure, and each comprises a first deep N-well N-MOS tube, a second deep N-well N-MOS tube, a third deep N-well N-MOS tube, a fourth deep N-well N-MOS tube, a first N-MOS tube, a second N-MOS tube, a first resistor, a second resistor, a third resistor, a fourth resistor, a fifth resistor, a sixth resistor, a seventh resistor, and an eighth resistor; a deep N-well of the first deep N-well N-MOS tube is connected to a first end of the first resistor, a second end of the first resistor is connected to a first end of the second resistor and connected to a power supply voltage, and a second end of the second resistor is connected to a deep N-well of the second deep N-well N-MOS tube; a body end of the first deep N-well N-MOS tube is connected to a first end of the third resistor, a second end of the third resistor is connected to a source of the first deep N-well N-MOS tube and connected to a drain of the third deep N-well N-MOS tube; a body end of the second deep N-well N-MOS tube is connected to a first of the fourth resistor, a second end of the fourth resistor is connected to a source of the second deep N-well N-MOS tube and connected to a drain of the fourth deep N-well N-MOS tube; a deep N-well of the third deep N-well N-MOS tube is connected to a first end of the fifth resistor, a second end of the fifth resistor is connected to a first end of the sixth resistor and connected to the power supply voltage, a second end of the sixth resistor is connected to a deep N-well of the fourth deep N-well N-MOS tube; a body end of the third deep N-well N-MOS tube is connected to a first end of the seventh resistor, a second end of the seventh resistor is connected to a source of the third deep N-well N-MOS tube and connected to a drain of the first N-MOS tube; a body end of the fourth deep N-well N-MOS tube is connected to a first end of the eighth resistor, a second end of the eighth resistor is connected to a source of the fourth deep N-well N-MOS tube and connected to a drain of the second N-MOS tube; and a source of the first N-MOS tube is connected to a source of the second N-MOS tube and grounded.
 16. The electronic device of claim 15, wherein: the first deep N-well N-MOS tube and the second deep N-well N-MOS tube are both a deep N-well normal voltage threshold thick gate oxide N-MOS tube.
 17. The electronic device of claim 15, wherein: the third deep N-well N-MOS tube and the fourth deep N-well N-MOS tube are both a deep N-well low voltage threshold thin gate oxide N-MOS tube.
 18. The electronic device of claim 15, wherein: the first N-MOS tube and the second N-MOS tube are both a low voltage threshold thin gate oxide N-MOS tube. 